Neutrino Physics in Slovakia Fedor Š imkovic Comenius University, Bratislava

1. RECFTA-meeting, Košice, May 27, 2011 Neutrino Physics in Slovakia Fedor Šimkovic Comenius University, Bratislava Fedor Simkovic

2. Neutrino Physicists in Slovakia Department of Nuclear Physics and Biophysics Comenius University, Bratislava Participants (theory): F. Šimkovic,R. Dvornický (PhD), R. Hodák (PhD) Participants (experiment): P. Povinec, K. Holý, I. Sýkora, J. Staníček, M. Pikna P. Valko, J. Szarka, J. Vanko, M. Mülerová, R. Hodák (PhD), P. Valko (PhD) Experiments: 0nbb (NEMO3, SuperNEMO – 2004/2010 TGV-2002, COBRA-2005) 0nee (on 74Se in Bratislava, proposal for LSM Modane) - 2009 charge-changing reaction at RCNP Osaka - 2008 beta beams at ISOLDE -2009 Fedor Simkovic

3. OUTLINE • 0nbb-decay (theory+experiment) • 0nee-decay (theory+experiment) • 2nbb-decay and bosonicneutrinos (theory) • Measuringofmassofn withb-decayof3H, 187Re ... • (theory) • Towardsthedetectionofrelicneutrinos (theory) • Beta beams (experiment) • Grants and problems Fedor Simkovic

4. Neutrinoless Double-Beta Decay (theory and experiment) What is the nature of neutrinos? ComeniusUniversitygroup in collaborationwith - NEMO3, SuperNEMOColl. - Tuebingen, CALTECH, Ioannina, Valparaiso, Dubna, ... Study of the 0nbb-decay is one of the highest priority issues in particle and nuclear physics  GUT’s Only the 0νββ-decay can answer this fundamental question (plus absolute mass scale of n’s, hierarchy, CP violation) Fedor Simkovic

5. The 0nbb-decay is a particle, nuclear and atomic physics problem Two basic categories are long-range (exchange of light Majorana n) and short-range (exchange of heavy n, squarks, gluinos …) contributions to the 0nbb-decay Fedor Simkovic

6. Sterile neutrino in 0nbb-decay Matrix element depends on n-mass Beneš, Faesler, F.Š., Kovalenko, PRD 71 (2005) 077901 Fedor Simkovic

7. Squark mixing SUSY mechanism Mixing betweenscalarsuperpartners of the left- and right-handed fermions A. Faessler, Th. Gutsche, S. Kovalenko, F.Š., PRD 77 (2008) 113012 Hirsch, Klapdor-Kleingrothaus, Kovalenko PLB 372 (1996) 181 L R Fedor Simkovic

8. Co-existence of 2, 3 or more mechanisms of the 0nbb-decay It is well-known that there exist many mechanisms that may contribute to the 0nbb. Let consider 3 mechanisms: i) light n-mass mechanism, ii) heavy n-mass mechanism, iii) R-parity breaking SUSY mechanism with gluino exchange and CP conservation Claim of evidence: Bilenky, Faessler, Potzel, F.Š, arXiv: 1104.1952[hep-ph] Faessler, Fogli, Lisi, Rotunno, F.Š., arXiv: 1104.3716[hep-ph] Faessler, Meroni, Petcov, F.Š., Vergados, arXiv: 1103.2334, accepted in PRD F.Š., Vergados, Faessler, PRD 82, 113015 (2010) Fedor Simkovic

9. Fréjus Underground Laboratory: 4800 m.w.e. 100Mo (6.914 kg) T1/20nbb> 4.6 1023 years Qbb = 3034 keV |mbb| < 2.7 eV NEMO 3 82Se (0.932 kg) T1/20nbb> 1.0 1023y Qbb = 2995 keV|mbb| < 4.1 eV NEMO3 experiment 2nbb-decay ~106 events Fedor Simkovic

10. SuperNEMO project Objective: to built a detector sensitive to 2 1026 y Collaboration NEMO + new labs ~ 70 physicists, 11 countries, 27 laboratories USA MHC INL U. Texas Japan U. Saga KEK U Osaka Marocco Fes U. Russia JINR Dubna ITEP Mosow Kurchatov Institute Finland U. Jyvaskula UK UC London U Manchester IC London Ukraine INR Kiev ISMA Kharkov France CEN Bordeaux IReS Strasbourg LAL ORSAY LPC Caen LSCE Gif/Yvette Slovaquia U. Bratislava Spain U. Valence U. Saragosse U. Barcelone Czech Republic Charles U. Prague IEAP Prague F. Piquemal (CENBG)Nuppec Bordeaux, November 7-8 2006

11. Emanation of 222Rn from the Hamamatsu photomultiplier R6594 (Karol Holý group) Scheme of themeasurement AR – argon reservoir; C – water trap; S – silica gel; CH1 ... CH6 – cooled charcoal columns; SA – sample; ECH – emanation chamber; G – gas meter; F – flow rate meter. Charcoal columns: V = 10mℓ; mCH = 2g; type = DB1; ARa,CH = (7.50 ± 0.02)Bq/kg

12. Modulation of the radon emanation measurement We used small emanation chamber in Bratislava V = 2.5 ℓ, Material of walls: plexiglas, Thickness of walls: 10 cm Plexiglass decrease background emanation of radon approximately 10times. Our detection limit for radon exhalation is now: ~ 3∙10-9 Bq∙s-1

13. The double beta decay process can be observed due to nuclear pairing interaction that favors energetically the even-even nuclei over the odd-odd nuclei The NMEs for 0nbb-decay must be evaluated using tools of nuclear theory Fedor Simkovic

14. Nuclear structure approaches The 0nbb-decay NMEs (Status:2010) Large Scale Shell Model: Caurier, Menendez, Nowacki, Poves, PRL 100, 052503 (2008). (Renormalized) QRPA: Šimkovic, Faessler, Müther, Rodin, Stauf, PRC 79, 055501 (2009). Interacting Boson Model: Barea, Iachello, PRC 79, 044301 (2009). Projected Hartree-Fock-Bogoliubov: Rath, Chandra, et al. PRC 82, 064310 (2010). Energy Dendity Functional appr.: Rodrígez, Martínez-Pinedo, arXiv:1008.5260 [nucl-th]. Half-life T1/2 for mbb= 50 meV Bratislava contributions •  Role of occupancies of individual • orbits •  Brueckner short-range correlations • Effect of nuclear deformation • The case of competing of 0nbb-decay • mechanisms

15. A claim of evidence and other experiments (current status) Fedor Simkovic Faessler, Fogli, Lisi, Rodin, Rotunno, F.Š., PRD 79, 053001 (2009)

16. The cross sections of (t,3He) and (d,2He) reactions give B(GT±) for b+ and b-, product of the amplitudes (B(GT)1/2) entering the numerator of M2nGT Closure 2nbb-decay NME SSD hypothesis Fedor Simkovic Grewe, …Frekers at al, PRC 78, 044301 (2008)

17. RCNP of Osaka University Ejiri group (Osaka), Frekers group (Muenster), Hodák, Povinec, Šimkovic (Bratislava) Facility founded in 1971 • Dispersion matching technique • High resolution - 30 keV • High intensities ~10 pnA High resolution spectrometer Grand Raiden

18. Research programs: Nuclearphysics, fundamental physics, nuclear chemistry and biology Beam requirements: Charge exchange reactions for studies of double β-decay NME • Type of particle: 3He • Beam energy: 420 MeV • Beam intensity: 20 nA • Energy resolution: ΔE ≤ 100 keV Targets: • 128,130,nat Te (≈ 1 mg/cm2) • 69,71,nat Ga • Measure B(GT+) through (n,p)-type reaction • Measure B(GT−) through (p,n)-type reaction • Phase can not be measured • Simple relation   B(GT)

19. Neutrinoless Double-Electron Capture (theory and experiment) Povinec,´Holý, Sýkora, Staníček, Šimkovic ...(ComeniusUniversity) TGV collaboration, Šteklgroup (Prague), Brudanin(Dubna) Frekersgroup (U. Muenster) Blaum (MPI Heidelberg) Krivoruchenko (ITEP Moscow) Fedor Simkovic

20. Oscillations of atoms Oscillation ofatoms (lepton number violation) F.Š., M. Krivoruchenko, Phys.Part.Nucl.Lett. 6 (2009) 485. In analogy with oscillations of n-anti{n} (baryon number violation) Oscillations of stable atoms(G=0) Oscillations of unstable atoms (G≠0)Double electron capture (resonant enhancement) Fedor Simkovic

21. Data analysis of most likely resonant transitions Half-life of a particular isotope 1chance of100 forT1/2< 1025 y 10 100 < 1027 y Number of transitions n with half –life Ta1/2 < T1/2 M. Krivoruchenko, F.Š., D. Frekers,A. Faessler, arXiv: 1012.1204[hep-ph] accepted in Nucl. Phys. A Fedor Simkovic

22. Improved Q-value measurements Klaus Blaum (MPI Heidelberg) 152Gd152Sm (Eliseev, et al., F.Š, M. Krivoruchenko, PRL 106, 052504 (2011)) (F.Š., Krivoruchenko, Faessler, PPNP 66, 446 (2011) Fedor Simkovic

23. Experiment in Bratislava! 74Se Muenster and Bratislava groups T1/2 > 4.3 1019 years Frekers, Puppe, Thies, Povinec, Šimkovic, Staníček, Sýkora, accepted in NPA Fedor Simkovic

24. TGV experiment in Modane underground laboratory theoretical support 10 g of 106Cd T1/2 2nee (106Cd) > 3.6 1020 y TGV Coll, Rukhadze et al., NPA 852, 197 (2011) T1/2 0nee (106Cd) > 1.1 1020 y Fedor Simkovic

25. Two-neutrino Double-Beta Decay and statisticalpropertiesofn (theory) Šimkovic, Dvornický(ComeniusUniversity) Barabash (ITEP Moscow) Smirnov (ICTP Trieste) Dolgov (U. Ferrara) Fedor Simkovic

26. Mixed statistics for neutrinos Definnition of mixed state with commutation Relations Amplitude for 2 Decay rate Partly bosonic neutrino requires knowing NME or log ft values for HSD or SSD ( calculations coming up soon ) Fedor Simkovic

27. Looking for a signature of bosonic n 2nbb-decayhalf-lives (0+→0+g.s., 0+→0+1, 0+→2+1)  HSD – NME needed  SSD – log ftEC, log ftbneeded Normalized differential characteristics The single electron energy distribution The distribution of the total energy of two electrons Angular correlations of two electrons (free of NME and log ft) Fedor Simkovic

28. Mixed n excluded for sin2c < 0.6 (NEMO3 data) 100Mo → 100Ru (SSD) Fedor Simkovic Barabash, Dolgov, Dvornický, F. Š., Smirnov, NPB 783, 90 (2007)

29. Measuring mass of neutrinos with b-decays of 3H, 187Re, 115In and electron capture of 163Ho (theory) Šimkovic, Dvornický(ComeniusUniversity) Muto (TokyoTechnical U.) Faessler (Tuebingen) Fedor Simkovic

30. Standard approach • non-relativistic nuclear w.f. • nuclear recoil neglected • phase space analysis Relativistic approach to 3H decaynuclear recoil (3.4 eV) taken into account • Relativistic EPT approach (Primakoff) • Analogy with n-decay • (3H,3He) ↔ (n,p) • nuclear recoil of 3.4 eV by Eemax • relevant only phase space Numerics: Practically the same dependence of Kurie function on mn for Ee≈ Eemax F.Š., R. Dvornický, A. Faessler, PRC 77 (2008) 055502 Fedor Simkovic

31. Spectrum of emitted electrons in rhenium b-decay Dvornický, F. Š., Muto, Faessler, PPNP (2009) Electron p3/2 decay channel clearly dominates Electron in the p3/2state Electron in the s1/2state In agreement with Arnaboldi et al.: PRL 96, 042503 (2006) Fedor Simkovic

32. Kurie plots for rhenium (MARE) and tritium (KATRIN)b-decay Rhenium Tritium y=Eemax-Ee Properly normalized Kurie functions are practically the same by the endpoint ! K(E)/BRe  K(y)/BT Dvornický, Muto, F.Š, Faessler, PRC 83, 045502 (2011) Fedor Simkovic

33. Towards laboratory detection of relic neutrinos (theory) Šimkovic, Hodák(ComeniusUniversity) Kovalenko(UniversityValparaiso) Krivoruchenko(ITEP Moscow) Faessler (U. Tuebingen) Fedor Simkovic

34. Detection of relic neutrinos by KATRIN experiment Assuming MF=1, MGT=3 and =<> the capture rate KATRIN will use ~50 g of 3H Faessler, Hodák, Kovaenko, F.Š, arXiv: 1102.1799[hep-ph] accepted in J. Phys. G Even considering effect of clustering of n,/<> ~ 103-104: Nncapt(KATRIN) < 1 y-1 Fedor Simkovic

35. 35 Sterile relic neutrino detection using nh capture on 3He nh+ 3He → 3H- + e+ Mixing of neutrinos Capture rate per atom Hodák, F.Š., Kovaenko, Faessler, PPNP 66, 452 (2011) Production rate for 1kg of 3He Fedor Simkovic

36. Beta Beams at CERN (experiment) ThierryStoragroup (CERN) RastislavHodák, Peter Valko (ComeniusUniversity) Fedor Simkovic

37. Beta beams concept Phys. Lett. B 532, (2002), 166-172 • Idea by Piero Zucchelli (2002) • Aim: Production of pure and collimatedultra-relativistic (anti)neutrino beams from the beta decay of radioactive ions circulating in a storage ring. • Physical applications: • High energy  Neutrino oscillation physics (mixing angle θ13 and CP violation phase) • Low energy Cross-sectionsofneutrino-nucleus interaction Beta beams scenario 6He/18Ne Orme Ch., arXiv:1004.0939v1 (2010) • Ion choice:6He and 18Ne • Based on existing technology and machines • Production of νeand anti-νe over 10 years: • - 2.9 x1019 anti-ν from 6He (3.3 x10136He/s) • - 1.1 x1019 ν from 18Ne (2.1 x101318Ne/s)

38. 6He production • Threshold: 0.6 MeV • Peak cross-section: 105 mb@ 3MeV N. Thiolliere et al., EURISOL-DS • 6He can be achieved: − 2 x10136He/s 100kW, 1 GeV proton beam − 1 x10146He/s 200kW, 2 GeV p beam in-targetproduction BeO Target p (1.4 GeV) ISOLDE experiment - CERN, GANIL and Weizmanncollaboration (p‐n) WConverter

39. 18Ne production • Threshold: 16 MeV • Peak cross-section: 1.6mb@ 30 MeV Conceptual target loop (19F(p, 2n)18Ne) • Melting point of NaF-ZrF4≈ 500°C • Hastelloy Nalloy (Ni based) – excellent saltcorrosion resistance • Cooling – by circulating molten salt

40. Publications - Citations (2006-2011) About 60 publications in refereed journals with about 700 citations Fedor Simkovic

41. Grants -Finances EU project: (2004-09) Integrated Large Infrastructures for Astroparticle Science, RII3-CT-2004-506222 (theory) DFG project: (2005-11) Nuclei as laboratory to test lepton number/flavor violation (theory) JINR project: (2005-11) Grand unification, fundamental rare processes and nuclear structure (theory) Slovak projects: VEGA(2006-09) Massive neutrinos and double beta decay VEGA(2009-11) Massive neutrinos in astro-, particle and nuclear physics (theory) Fedor Simkovic

42. Can we get some money for experimental activities? EU project ILIAS-next (theory and experiment), submitted in 2009 and 2010, not approved (twice 13.5 points from 15) EU structural funds for Slovakia (theory and experiment), Project for construction of small underground laboratory, positive referee’s reports, not approved - not enough money allocated for call (2010)?! But, we need such facility (Fukushima)! APVV project SuperNEMO experiment (theory and experiment), 2011, not approved positive referee’s reports, Slovak referees gave not enough points 89/100 and 91/100 Slovak particip. in ASPERA? ASPERA meeting in Bratislava in 2008. Suggestion for the APVV to enter ASPERA within ERANET (34 000 EUR). Answer: NO Institute for particle and astroparticle physics! Can we get support for our astroparticle activities from Slovak-CERN commision? Fedor Simkovic

43. We have no end of fun with neutrino physics. Mathematics is Egyptian Neutrino physics is Babylonian We have to communicate more with neutrinos. Fedor Simkovic